DE102019135071A1 - Compression therapy system comprising a photoplethysmographic sensor - Google Patents

Abstract

The invention relates to a system for compression therapy and a computer-implemented method for checking compression therapy. The system comprises a compression means, a photoplethysmographic sensor (3) and a computer. Measured values from the photoplethysmographic sensor (3) can be transferred to the computer. Furthermore, the computer comprises means for carrying out a method for checking the compression therapy, the method comprising the following steps: i. Receiving measured values from the photoplethysmographic sensor (3) during the compression therapy, ii. Determining a replenishment time on the basis of the measured values received from the photoplethysmographic sensor (3), iii. Check whether the specific replenishment time falls below a specified lower limit, iv. optional output of an alarm if the test shows that the specified lower limit is not reached.

Description

The invention relates to a system for compression therapy and a computer-implemented method for checking compression therapy.

Photoplethysmography is an examination method used in the diagnosis of venous insufficiency. The patient performs movements (for example standing toes or the like) in order to empty the veins in the lower leg through the activity of the muscles. Then the patient rests again so that the veins can refill with blood. The time it takes for the veins to reach their original state of filling with blood, the so-called replenishment time, is used as a diagnostic tool. This is the replenishment time in (vein) healthy subjects 25th Seconds or more. A lower value for the refill time is taken as an indication of venous insufficiency. From a technical point of view, an infrared sensor (IR sensor) is used in photoplethysmography to determine the replenishment time. The infrared sensor irradiates a point on the patient's lower leg with infrared light, which is then reflected back to the sensor to different degrees depending on the amount of blood in the veins. The sensor detects the reflected infrared light and the replenishment time can be determined from the measurement curve obtained.

Compression bandages are often used to treat venous insufficiency. It is already known from the prior art to equip compression bandages with pressure sensors. The pressure values determined are intended to provide information on whether the compression bandage is correctly applied to the patient's body so that it can be therapeutically effective. Undoubtedly, such pressure sensors can make progress in compression therapy. However, the effectiveness of compression therapy can only be checked indirectly with pressure measurements. In addition, the pressure values required for the therapeutic effectiveness of compression therapy can differ from patient to patient. It would therefore be desirable to have a possibility with which the effectiveness of compression therapy can be checked more directly and in as much as possible the same way for as many patients as possible. The object of the present invention is to provide such a possibility. The object is achieved with a system according to claim 1 and a computer-implemented method according to claim 16.

1. i. Empfangen von Messwerten des photoplethysmographischen Sensors während der Kompressionstherapie,
2. ii. Bestimmen einer Wiederauffüllungszeit anhand der empfangenen Messwerte des photoplethysmographischen Sensors,
3. iii. Prüfen, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Untergrenze unterschreitet,
4. iv. optional Ausgabe eines Alarms, wenn die Prüfung ergibt, dass die vorgegebene Untergrenze unterschritten wird.

According to the invention, the system for compression therapy comprises a compression means, a photoplethysmographic sensor (PPG sensor) and a computer. Measured values from the photoplethysmographic sensor can be transferred to the computer. Furthermore, the computer comprises means for carrying out a method for checking the compression therapy, the method comprising the following steps:

1. i. Receiving readings from the photoplethysmographic sensor during compression therapy,
2. ii. Determining a replenishment time on the basis of the measured values received from the photoplethysmographic sensor,
3. iii. Check whether the specific refill time falls below a specified lower limit,
4. iv. optional output of an alarm if the test shows that the specified lower limit is not reached.

The aforementioned means of the computer are in particular a processor and a computer program. The latter is the subject of claim 17 and is described in more detail below.

The present invention is based on the idea that photoplethysmography can be used not only for diagnostic purposes to detect a venous disease, but also to check compression therapy. This is because the refilling time measured in photoplethysmography should in any case be extended by compression therapy in a patient with venous disease if the compression therapy is therapeutically effective and leads to improved venous function. An effective compression therapy should therefore lead to a normal or at least improved finding in the photoplethysmography, which according to the inventive idea is used as a control option for the effectiveness of the compression therapy. The procedure for checking the compression therapy is basically as follows: With the compression therapy system in place, the patient carries out a movement program that is customary for photoplethysmography, including a rest phase. The compression therapy system determines the replenishment time on the basis of the measured values and checks whether it falls below a specified lower limit. If this is the case, an alarm can be issued. The alarm alerts the patient to insufficient effectiveness of compression therapy. The inadequate effectiveness could be the result of insufficient compression performance of the compression therapy system. Such an insufficient compression performance can occur, for example, if a bandage used as a compression means is too loose on the too part of the body to be treated. The effectiveness of the compression therapy can be improved or restored by putting on the bandage again after the alarm message and with a higher tension. Overall, the effectiveness of compression therapy can thus be checked very directly and easily in many cases. Further advantages of the invention are indicated in the preferred embodiments described below.

The compression therapy system according to the invention could also be equipped with a pressure sensor. However, this is not absolutely necessary or intended. The system can also not include a pressure sensor.

The compression means within the meaning of the present invention is intended in particular to be attached to a lower leg of a person. The compression means can be a compression bandage, a compression tube or a compression stocking. The compression bandage has the advantage that it is very adaptable. The compression hose and the compression stocking can be put on quickly and easily. Compression bandages are commercially available, for example from the patent applicant Paul Hartmann AG (Heidenheim, Germany) under the brand name Plütter ^®. Several of the aforementioned compression means can also be combined with one another. For example, a compression bandage can be used in combination with a compression stocking.

The photoplethysmographic sensor usually comprises a light source for infrared light and a photodetector. The light source is preferably a light emitting diode (LED). The photodetector is preferably a photodiode. The photodetector can detect the infrared light reflected from the tissue. Correspondingly, the measured values of the photoplethysmographic sensor according to the claims can include measured values of the photodetector with regard to the reflected infrared light.

For ease of use, it is advantageous if the system comprises a sensor unit with a substrate, the photoplethysmographic sensor being arranged on the substrate. The substrate of the sensor unit can be a printed circuit board, in particular a flexible printed circuit board. The attachment of the sensor unit to the patient's body or to the compression means can be facilitated by the fact that the printed circuit board is flexible. The flexible printed circuit board also improves the comfort of the compression therapy system in particular. The flexible printed circuit board is preferably a polymer film on which electronic components are applied, in particular printed.

In addition, the sensor unit can comprise a data acquisition unit. The data acquisition unit is designed to acquire the measured values from the photoplethysmographic sensor and to transmit them to the computer. Just like the sensor, the data acquisition unit can be arranged on the substrate of the sensor unit. However, it can also be connected to the substrate of the sensor unit with a connector, for example a cable. The data acquisition unit can comprise a microcontroller, a preamplifier and an analog-to-digital converter. Further possible electronic components of the data acquisition unit are mentioned below. The data acquisition unit can thus also represent a computer in itself. It is then even possible for the data acquisition unit to support the computer in carrying out individual steps of the verification process.

According to a particularly preferred embodiment of the invention, the sensor unit is designed to be adhesive and is provided detached from the compression means. For this purpose, the sensor unit preferably comprises an adhesive backing layer, the sensor unit then being able to be designed in the manner of a plaster. This embodiment has the particular advantages that the sensor unit can be easily attached to the patient's body without additional aids (such as an adhesive plaster) and the patient or the nursing staff can freely choose where the sensor unit should be placed to collect the measured values . On the other hand, it can also be provided that the sensor unit is connected to the compression means by the manufacturer. As a result, the creation of the system can be simplified and done more quickly.

The computer is preferably a mobile device. A smartphone or a tablet, in particular, can be considered as the mobile device for the invention. As a result, the number of electronic components can be minimized, because an existing, high-performance device belonging to the patient or the nursing staff can be used for data evaluation and data display. In addition, the handling and the wearing comfort of the compression therapy system can be improved in this way.

In a simple embodiment of the invention, the measured values of the photoplethysmographic sensor are transmitted to the computer in a wired manner. However, it is much more advantageous if the transmission of the measured values from the photoplethysmographic sensor to the computer is wireless takes place, the transmission preferably taking place via near field communication (NFC), Bluetooth or a wireless local area network (WLAN). As a result, the measured values can be transferred to any location and the handling and wearing comfort of the system can be improved. For the wireless data exchange, the compression therapy system can comprise one or more NFC transceivers, Bluetooth transceivers and / or WLAN transceivers. An NFC transceiver, a Bluetooth transceiver and / or a WLAN transceiver can in particular be contained in the data acquisition unit and the computer.

In order to improve the data security of the compression therapy system, it is also proposed that the measured values of the photoplethysmographic sensor be transmitted to the computer in encrypted form. The encryption can be carried out, for example, by the data acquisition unit. The decryption of the measured values can be carried out by the computer.

The photoplethysmographic sensor normally has its own energy source, the energy source preferably being a battery. That is, the compression therapy system normally further comprises an energy source, preferably a battery, for the photoplethysmographic sensor. The energy source can be encompassed by the sensor unit and arranged, for example, on its substrate.

In addition, advantageous embodiments of the invention can be specified with regard to the mode of operation of the computer. For example, it is preferred that the measured values from the photoplethysmographic sensor are received immediately after the measured values have been recorded by the sensor. This allows the user of the system to be quickly informed about the effectiveness of the compression therapy. It is also preferred that the reception and thus in particular also the generation of the measured values of the photoplethysmographic sensor take place on command of a user. In the present case, permanent monitoring of the sensor readings is neither necessary nor sensible, since the patient has to complete a special exercise program for the verification procedure followed by a rest phase, which he will only do when necessary and at most at regular intervals to check the compression therapy. This embodiment of the invention simultaneously reduces the energy consumption of the photoplethysmographic sensor.

The lower limit for the replenishment time can be selected from a range from 10 seconds to 25 seconds, preferably from 15 seconds to 25 seconds, more preferably from 20 seconds to 25 seconds and particularly preferably from 23 seconds to 25 seconds. In particular, the lower limit for the replenishment time is 25 seconds, which would correspond to a normal finding.

In a particularly preferred and particularly advantageous embodiment of the invention, the method for checking the compression therapy also checks whether the specific refill time exceeds a predetermined upper limit. An alarm is optionally output if the check shows that the specified upper limit is exceeded. In this way, a deficient blood supply to the treated body part caused by excessive compression could be recognized and the safety of the compression therapy system could be improved.

1. i. Empfangen von Messwerten des photoplethysmographischen Sensors während der Kompressionstherapie,
2. ii. Bestimmen einer Wiederauffüllungszeit anhand der empfangenen Messwerte des photoplethysmographischen Sensors,
3. iii. Prüfen, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Untergrenze unterschreitet,
4. iv. optional Ausgabe eines Alarms, wenn die Prüfung ergibt, dass die vorgegebene Untergrenze unterschritten wird,
5. v. Prüfen, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Obergrenze überschreitet,
6. vi. optional Ausgabe eines Alarms, wenn die Prüfung ergibt, dass die vorgegebene Obergrenze überschritten wird.

The method can then comprise the following steps:

1. i. Receiving readings from the photoplethysmographic sensor during compression therapy,
2. ii. Determining a replenishment time on the basis of the measured values received from the photoplethysmographic sensor,
3. iii. Check whether the specific refill time falls below a specified lower limit,
4. iv. optional output of an alarm if the test shows that the specified lower limit is not reached,
5. v. Check whether the specific replenishment time exceeds a specified upper limit,
6. vi. optional output of an alarm if the test shows that the specified upper limit is exceeded.

Steps iii. and iv. can also be done with steps v. and vi. be swapped in their order.

The upper limit has a higher value than the lower limit. Consequently, the test with regard to the upper limit could also be omitted if the test with regard to the lower limit previously showed that the lower limit was not reached. Furthermore, the check with regard to the lower limit could also be omitted if the check with regard to the upper limit has previously shown that the upper limit has been exceeded.

1. i. Empfangen von Messwerten des photoplethysmographischen Sensors während der Kompressionstherapie,
2. ii. Bestimmen einer Wiederauffüllungszeit anhand der empfangenen Messwerte des photoplethysmographischen Sensors,
3. iii. Prüfen, ob die bestimmte Wiederauffüllungszeit außerhalb eines vorgegebenen Bereiches liegt,
4. iv. optional Ausgabe eines Alarms, wenn die Prüfung ergibt, dass die bestimmte Wiederauffüllungszeit außerhalb des vorgegebenen Bereiches liegt.

In this particularly preferred embodiment of the invention, the lower limit and the upper limit form a range. If the specific refill time is within this range, compression therapy is considered effective and safe and no alarm is given. If, on the other hand, the specific replenishment time is outside the range, the compression therapy is considered ineffective (especially if the lower limit is not reached) and / or unsafe (especially if the upper limit is exceeded) and an alarm is issued. Accordingly, the invention also comprises a method for checking compression therapy with the following steps:

1. i. Receiving readings from the photoplethysmographic sensor during compression therapy,
2. ii. Determining a replenishment time on the basis of the measured values received from the photoplethysmographic sensor,
3. iii. Check whether the specific replenishment time is outside a specified range,
4. iv. optional output of an alarm if the test shows that the specific refill time is outside the specified range.

The upper limit for the replenishment time can be selected from a range from 30 seconds to 180 seconds, preferably from 35 seconds to 90 seconds, more preferably from 40 seconds to 90 seconds and particularly preferably from 45 seconds to 90 seconds. In particular, the upper limit for the replenishment time is 60 seconds. With a lower limit of 25 seconds, for example, there would then be a preset range for the refill time of 25 seconds to 60 seconds.

If the lower limit for the refill time is not reached or the upper limit for the refill time is exceeded, the optional alarms can be output as already shown. The alarms are output in particular visually and / or acoustically.

The system usually also comprises an input device and an output device. The input means and the output means are preferably components of the computer. The input means can serve to receive commands or specifications from the user. The output means can serve to display the measured values and to output the alarm. A touch screen of, for example, a smartphone or tablet can function as both input means and output means. The output means can also be a loudspeaker (acoustic alarm). Every smartphone or tablet these days has a touch screen and a speaker.

Typically, the system also includes a disk. The data carrier is also preferably part of the computer. The data carrier can be used to store computer programs and the measured values received. This enables the user to understand all the measured values received during the course of the compression therapy. The data carrier can be a hard disk, a semiconductor drive (solid-state drive, SSD) or an SD card (secure digital memory card). The compression therapy system can also have more than one data carrier. In particular, the aforementioned data acquisition unit can also comprise a data carrier. It is also conceivable that the sensor measured values from the compression therapy system are stored in an online-based data storage service (cloud) or on a local network drive.

1. i. Erzeugen von Messwerten mit einem photoplethysmographischen Sensor während der Kompressionstherapie, um die Wirksamkeit der Kompressionstherapie zu überprüfen,
2. ii. Übertragen der Messwerte des photoplethysmographischen Sensors während der Kompressionstherapie an einen Computer,
3. iii. Bestimmen einer Wiederauffüllungszeit anhand der Messwerte des photoplethysmographischen Sensors durch den Computer,
4. iv. Prüfen durch den Computer, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Untergrenze unterschreitet,
5. v. optional Ausgabe eines Alarms durch den Computer, wenn die Prüfung ergibt, dass die vorgegebene Untergrenze unterschritten wird.

The present invention also relates to a computer-implemented method for checking compression therapy. This procedure consists of the following steps:

1. i. Generating measured values with a photoplethysmographic sensor during compression therapy in order to check the effectiveness of the compression therapy,
2. ii. Transferring the measured values of the photoplethysmographic sensor during compression therapy to a computer,
3. iii. Determination of a replenishment time on the basis of the measured values of the photoplethysmographic sensor by the computer,
4. iv. Check by the computer whether the specific replenishment time falls below a specified lower limit,
5. v. optional output of an alarm by the computer if the test shows that the specified lower limit is not reached.

As part of step ii above. the measured values of the photoplethysmographic sensor are received by the computer.

The computer-implemented method can advantageously be carried out with all of the embodiments of the compression therapy system described here.

The invention also relates to a computer program for carrying out the computer-implemented method according to the invention. A computer program product is claimed, comprising commands which, when the program is executed by a compression therapy system according to the invention, cause the program to carry out the steps i. to v. (i.e. all steps), steps iii. to v. or at least steps iii. and iv. of the above-mentioned computer-implemented method. What is also claimed is a computer-readable data carrier on which such a computer program product is stored. The computer-readable data carrier can in particular be a CD, DVD or a USB stick. Finally, a data carrier signal is also claimed that transmits such a computer program product. The data carrier signal can originate, for example, from an online-based sales platform (app store such as Google Play) and transfer the computer program to a smartphone or tablet for installation.

Examples and figures

The invention is to be explained and illustrated in greater detail using the examples and figures described below.

1 shows a sensor unit 1 . The sensor unit 1 is a component of a first preferred embodiment of the compression therapy system according to the invention. The sensor unit 1 comprises a substrate 2 , which is a preferably flexible printed circuit board. On the substrate 2 is a photoplethysmographic sensor 3 arranged. Usually the sensor has 3 a light source for infrared light and a photodetector. One connector 4th then connects the substrate 2 with a data acquisition unit 5 . This has the task of receiving the measured values from the sensor 3 to detect and to transmit to a computer (not shown) wirelessly, for example by means of Bluetooth or NFC. The data acquisition unit 5 comprise a data carrier and a Bluetooth or NFC transceiver (not shown). A smartphone in particular is provided as the computer. The computer can then check the received measurement data in the manner provided according to the invention and alert the user if the compression therapy is found to be inadequate.

2 shows a sensor unit 6th as part of a second preferred embodiment of the compression therapy system according to the invention. The sensor unit 6th differs from the sensor unit 1 only in that it is designed in the manner of a plaster. The plaster-like appearance results from a backing layer 7th ("Backing"), which is made adhesive on one side and on the substrate 2 , the connector 4th and the data acquisition unit 5 is additionally attached.

With the free, adhesive edge area 8th the back layer 7th can the sensor unit 6th be glued to the patient's body. The back layer 7th out 2 has an oval shape.

The back layer 7th but can also have a different shape, for example a rectangular shape.

Application example

• - Part of the body to be treated: lower leg of a person
• - Components of the compression therapy system used:
  • - sensor unit 1 or sensor unit 2 out 1 respectively 2
  • - a compression bandage (as compression means, which is provided separately from the sensor unit)
  • - a smartphone (as a computer with a data carrier, a Bluetooth and NFC transceiver, a touch screen and a speaker)
• - Time of the control measurements: takes place at the command of a user
• - Course of treatment (in chronological order):
  1. i. Attaching the sensor unit to a point on the lower leg where the venous blood volume is to be measured. For fastening the sensor unit 1 out 1 A sticking plaster from the medical field, for example Omniplast® from the patent applicant, can be used as an aid.
  2. ii. Wrap the lower leg with the compression bandage. The sensor unit is then arranged between the skin and the bandage. The time after putting on the compression bandage can be seen as the start of compression therapy.
  3. iii. Activation of an application ("app") installed on the smartphone, which is intended for processing the sensor measured values. A lower limit for the refill time is preset in the application. For example, a lower limit for the refill time of 25 seconds could be preset. If necessary, the user can adapt this presetting individually according to the specific medical conditions. Such an individual adjustment could be based on the result (i.e. the replenishment time) of a photoplethysmographic examination carried out prior to the compression therapy take place, which can also be carried out with the sensor unit and the smartphone of the present compression therapy system. If, for example, a refill time of only 10 seconds is determined for a patient prior to compression therapy, the preset lower limit for the refill time could be reduced from 25 seconds to 20 seconds, since the extension of the refill time by 10 seconds in this case is already a satisfactory and possibly could represent maximum therapeutic success. In addition, a likewise adjustable upper limit for the replenishment time of 60 seconds, for example, is preset in the application. The preset upper limit, like the preset lower limit, can therefore be individually adapted by the user in accordance with the specific medical conditions.
  4. iv. Start a control measurement using the application. The patient then carries out an exercise program followed by a rest phase. Measurement data from the photoplethysmographic sensor are transmitted from the sensor unit to the smartphone. As a result, the replenishment time is displayed to the user. If this falls below the set lower limit or exceeds the set upper limit, a corresponding alarm signal is output. This ensures that the user is always aware of the inadequate effectiveness and / or the possible dangerous situation based on the compression therapy.
  5. v. If an alarm signal is issued, appropriate action can be taken to eliminate the alarm condition. For example, if the lower limit is not reached, i.e. if the measured refill time is too low, the compression bandage can be removed and put on again with a higher tension. If the upper limit is exceeded, i.e. if the measured refilling time is too long, the compression bandage can be removed and put on again with less tension. If there is no alarm signal, compression therapy can be continued. The user can then be certain that the compression therapy is therapeutically effective and safe.
  6. vi. A new control measurement can be carried out at a later point in time that can be freely selected by the user. Like the control measurement in step iv. initiated by the user, because the data transmission and the data check only take place on request in connection with the aforementioned special movement and rest phase. In addition, the amount of transmitted measurement data can be reduced and the energy consumption of the sensor unit can be minimized. The application can advantageously remain open on the smartphone after it has been activated for the first time, so that it can remind the user when a new control measurement should be carried out (for example at intervals of two hours).

If necessary, it is also possible to first wrap the lower leg with the compression bandage and then to attach the sensor unit to the outside of the bandage. The prerequisite for this is that the bandage still allows sufficient infrared light to pass through to determine the replenishment time.

1. 1. System für eine Kompressionstherapie, umfassend
   • - ein Kompressionsmittel,
   • - einen photoplethysmographischen Sensor,
   • - einen Computer, wobei Messwerte des photoplethysmographischen Sensors an den Computer übertragen werden können, und wobei der Computer Mittel zur Ausführung eines Verfahrens zur Überprüfung der Kompressionstherapie umfasst, wobei das Verfahren die folgenden Schritte umfasst:
     1. i. Empfangen von Messwerten des photoplethysmographischen Sensors während der Kompressionstherapie,
     2. ii. Bestimmen einer Wiederauffüllungszeit anhand der empfangenen Messwerte des photoplethysmographischen Sensors,
     3. iii. Prüfen, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Untergrenze unterschreitet,
     4. iv. optional Ausgabe eines Alarms, wenn die Prüfung ergibt, dass die vorgegebene Untergrenze unterschritten wird.
2. 2. System nach Absatz 1, wobei das System keinen Drucksensor umfasst.
3. 3. System nach Absatz 1 oder 2, wobei das Kompressionsmittel eine Kompressionsbinde, ein Kompressionsschlauch oder ein Kompressionsstrumpf ist.
4. 4. System nach einem der vorangehenden Absätze, wobei der photoplethysmographische Sensor eine Lichtquelle für infrarotes Licht und einen Photodetektor umfasst, wobei die Lichtquelle vorzugsweise eine Leuchtdiode ist und der Photodetektor vorzugsweise eine Photodiode ist.
5. 5. System nach einem der vorangehenden Absätze, wobei das System eine Sensoreinheit mit einem Substrat umfasst, wobei der photoplethysmographische Sensor auf dem Substrat angeordnet ist.
6. 6. System nach Absatz 5, wobei es sich bei dem Substrat um eine Leiterplatte, insbesondere um eine flexible Leiterplatte, handelt.
7. 7. System nach Absatz 5 oder 6, wobei die Sensoreinheit eine Datenerfassungseinheit umfasst, wobei die Datenerfassungseinheit dafür ausgebildet ist die Messwerte von dem photoplethysmographischen Sensor zu erfassen und an den Computer zu übertragen.
8. 8. System nach einem der Absätze 5 bis 7, wobei die Sensoreinheit adhäsiv ausgebildet ist und losgelöst von dem Kompressionsmittel bereitgestellt wird, wobei die Sensoreinheit vorzugsweise eine adhäsive Rückschicht umfasst.
9. 9. System nach einem der Absätze 5 bis 7, wobei die Sensoreinheit mit dem Kompressionsmittel herstellerseitig verbunden ist.
10. 10. System nach einem der vorangehenden Absätze, wobei es sich bei dem Computer um ein mobiles Gerät, insbesondere ein Smartphone oder ein Tablet, handelt.
11. 11. System nach einem der vorangehenden Absätze, wobei die Übertragung der Messwerte des photoplethysmographischen Sensors an den Computer kabellos erfolgt, wobei die Übertragung vorzugsweise über eine Nahfeldkommunikation, Bluetooth oder ein drahtloses lokales Netzwerk erfolgt.
12. 12. System nach einem der vorangehenden Absätze, wobei die Übertragung der Messwerte des photoplethysmographischen Sensors an den Computer verschlüsselt erfolgt.
13. 13. System nach einem der vorangehenden Absätze, wobei der photoplethysmographische Sensor über eine eigene Energiequelle verfügt, wobei die Energiequelle vorzugsweise eine Batterie ist.
14. 14. System nach einem der vorangehenden Absätze, wobei das Empfangen der Messwerte des photoplethysmographischen Sensors unmittelbar nachdem die Messwerte von dem Sensor erfasst wurden erfolgt.
15. 15. System nach einem der vorangehenden Absätze, wobei das Empfangen der Messwerte des photoplethysmographischen Sensors auf Befehl eines Benutzers hin erfolgt.
16. 16. System nach einem der vorangehenden Absätze, wobei die Untergrenze aus einem Bereich von 10 Sekunden bis 25 Sekunden, bevorzugt von 15 Sekunden bis 25 Sekunden, mehr bevorzugt von 20 Sekunden bis 25 Sekunden und besonders bevorzugt von 23 Sekunden bis 25 Sekunden ausgewählt ist, wobei die Untergrenze insbesondere 25 Sekunden beträgt.
17. 17. System nach einem der vorangehenden Absätze, wobei in dem Verfahren zur Überprüfung der Kompressionstherapie weiterhin geprüft wird, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Obergrenze überschreitet, wobei optional ein Alarm ausgegeben wird, wenn die Prüfung ergibt, dass die vorgegebene Obergrenze überschritten wird.
18. 18. System nach Absatz 17, wobei die Obergrenze aus einem Bereich von 30 Sekunden bis 180 Sekunden, bevorzugt von 35 Sekunden bis 90 Sekunden, mehr bevorzugt von 40 Sekunden bis 90 Sekunden und besonders bevorzugt von 45 Sekunden bis 90 Sekunden ausgewählt ist, wobei die Obergrenze insbesondere 60 Sekunden beträgt.
19. 19. System nach einem der vorangehenden Absätze, wobei der Alarm/die Alarme visuell und/oder akustisch ausgegeben wird/werden.
20. 20. System nach einem der vorangehenden Absätze, wobei das System ein Eingabemittel und ein Ausgabemittel, insbesondere einen Berührungsbildschirm, umfasst.
21. 21. System nach einem der vorangehenden Absätze, wobei das System einen Datenträger umfasst.
22. 22. Computerimplementiertes Verfahren zur Überprüfung einer Kompressionstherapie, umfassend die folgenden Schritte:
    1. i. Erzeugen von Messwerten mit einem photoplethysmographischen Sensor während der Kompressionstherapie, um die Wirksamkeit der Kompressionstherapie zu überprüfen,
    2. ii. Übertragen der Messwerte des photoplethysmographischen Sensors während der Kompressionstherapie an einen Computer,
    3. iii. Bestimmen einer Wiederauffüllungszeit anhand der Messwerte des photoplethysmographischen Sensors durch den Computer,
    4. iv. Prüfen durch den Computer, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Untergrenze unterschreitet,
    5. v. optional Ausgabe eines Alarms durch den Computer, wenn die Prüfung ergibt, dass die vorgegebene Untergrenze unterschritten wird,
    6. vi. optional Prüfen durch den Computer, ob die bestimmte Wiederauffüllungszeit eine vorgegebene Obergrenze überschreitet,
    7. vii. optional Ausgabe eines Alarms durch den Computer, wenn die Prüfung ergibt, dass die vorgegebene Obergrenze überschritten wird.
23. 23. Computerimplementiertes Verfahren nach Absatz 22, wobei ein System nach einem der Absätze 1 bis 21 verwendet wird, um das Verfahren auszuführen.
24. 24. Computerprogrammprodukt, umfassend Befehle, die bei der Ausführung des Programmes durch ein System nach einem der Absätze 1 bis 21 dieses veranlassen,
    • - die Schritte i. bis v., oder
    • - die Schritte iii. bis v., oder
    • - die Schritte iii. und iv., oder
    • - die Schritte i. bis vii., oder
    • - die Schritte iii. bis vii, oder
    • - die Schritte iii., iv. und vi. nach Absatz 22 oder 23 auszuführen.
25. 25. Computerlesbarer Datenträger, auf dem das Computerprogrammprodukt nach Absatz 24 gespeichert ist.
26. 26. Datenträgersignal, das das Computerprogrammprodukt nach Absatz 24 überträgt.

Finally, features of the present invention are reproduced again in the form of claims in the following paragraphs 1 to 26.

1. 1. A system for compression therapy, comprising
   • - a compression device,
   • - a photoplethysmographic sensor,
   • a computer, wherein measured values of the photoplethysmographic sensor can be transmitted to the computer, and wherein the computer comprises means for carrying out a method for checking the compression therapy, the method comprising the following steps:
     1. i. Receiving readings from the photoplethysmographic sensor during compression therapy,
     2. ii. Determining a replenishment time on the basis of the measured values received from the photoplethysmographic sensor,
     3. iii. Check whether the specific refill time falls below a specified lower limit,
     4. iv. optional output of an alarm if the test shows that the specified lower limit is not reached.
2. 2. System according to paragraph 1, wherein the system does not include a pressure sensor.
3. 3. System according to paragraph 1 or 2, wherein the compression means is a compression bandage, a compression tube or a compression stocking.
4. 4. System according to one of the preceding paragraphs, wherein the photoplethysmographic sensor comprises a light source for infrared light and a photodetector, wherein the The light source is preferably a light emitting diode and the photodetector is preferably a photodiode.
5. 5. System according to one of the preceding paragraphs, wherein the system comprises a sensor unit with a substrate, wherein the photoplethysmographic sensor is arranged on the substrate.
6. 6. System according to paragraph 5, wherein the substrate is a printed circuit board, in particular a flexible printed circuit board.
7. 7. System according to paragraph 5 or 6, wherein the sensor unit comprises a data acquisition unit, wherein the data acquisition unit is designed to acquire the measured values from the photoplethysmographic sensor and to transmit them to the computer.
8. 8. System according to one of paragraphs 5 to 7, wherein the sensor unit is designed to be adhesive and is provided detached from the compression means, the sensor unit preferably comprising an adhesive backing layer.
9. 9. System according to one of paragraphs 5 to 7, wherein the sensor unit is connected to the compression means by the manufacturer.
10. 10. System according to one of the preceding paragraphs, wherein the computer is a mobile device, in particular a smartphone or a tablet.
11. 11. System according to one of the preceding paragraphs, wherein the transmission of the measured values of the photoplethysmographic sensor to the computer takes place wirelessly, the transmission preferably taking place via near-field communication, Bluetooth or a wireless local network.
12. 12. System according to one of the preceding paragraphs, wherein the transmission of the measured values of the photoplethysmographic sensor to the computer is encrypted.
13. 13. System according to one of the preceding paragraphs, wherein the photoplethysmographic sensor has its own energy source, the energy source preferably being a battery.
14. 14. System according to one of the preceding paragraphs, wherein the measurement values from the photoplethysmographic sensor are received immediately after the measurement values have been recorded by the sensor.
15. 15. System according to one of the preceding paragraphs, wherein the receiving of the measured values of the photoplethysmographic sensor takes place at the command of a user.
16. 16. System according to one of the preceding paragraphs, wherein the lower limit is selected from a range from 10 seconds to 25 seconds, preferably from 15 seconds to 25 seconds, more preferably from 20 seconds to 25 seconds and particularly preferably from 23 seconds to 25 seconds, the lower limit being in particular 25 seconds.
17. 17. System according to one of the preceding paragraphs, wherein in the method for checking the compression therapy it is further checked whether the specific refill time exceeds a predetermined upper limit, an alarm optionally being output if the test shows that the predetermined upper limit is exceeded.
18. 18. System according to paragraph 17, wherein the upper limit is selected from a range from 30 seconds to 180 seconds, preferably from 35 seconds to 90 seconds, more preferably from 40 seconds to 90 seconds and particularly preferably from 45 seconds to 90 seconds, the Upper limit is in particular 60 seconds.
19. 19. System according to one of the preceding paragraphs, wherein the alarm (s) is / are emitted visually and / or acoustically.
20. 20. System according to one of the preceding paragraphs, wherein the system comprises an input means and an output means, in particular a touch screen.
21. 21. System according to one of the preceding paragraphs, wherein the system comprises a data carrier.
22. 22. A computer-implemented method for testing compression therapy, comprising the following steps:
    1. i. Generating measured values with a photoplethysmographic sensor during compression therapy in order to check the effectiveness of the compression therapy,
    2. ii. Transferring the measured values of the photoplethysmographic sensor during compression therapy to a computer,
    3. iii. Determination of a replenishment time on the basis of the measured values of the photoplethysmographic sensor by the computer,
    4. iv. Check by the computer whether the specific replenishment time falls below a specified lower limit,
    5. v. optional output of an alarm by the computer if the test shows that the specified lower limit is not reached,
    6. vi. optionally checking by the computer whether the specific replenishment time exceeds a predetermined upper limit,
    7. vii. optional output of an alarm by the computer if the test shows that the specified upper limit is exceeded.
23. 23. Computer-implemented method according to paragraph 22, wherein a system according to one of paragraphs 1 to 21 is used to carry out the method.
24. 24. Computer program product, comprising commands which, when the program is executed by a system according to one of paragraphs 1 to 21, cause this to happen,
    • - the steps i. to v., or
    • - steps iii. to v., or
    • - steps iii. and iv., or
    • - the steps i. to vii., or
    • - steps iii. to vii, or
    • - steps iii., iv. and vi. to be carried out in accordance with paragraph 22 or 23.
25. 25. Computer-readable data carrier on which the computer program product according to paragraph 24 is stored.
26. 26. Data carrier signal which the computer program product according to paragraph 24 transmits.

Claims (19)

Compression therapy system, comprising - a compression device, - a photoplethysmographic sensor (3), - A computer, wherein measured values of the photoplethysmographic sensor (3) can be transmitted to the computer, and wherein the computer comprises means for carrying out a method for checking the compression therapy, the method comprising the following steps: i. Receiving measured values from the photoplethysmographic sensor (3) during compression therapy, ii. Determining a replenishment time on the basis of the measured values received from the photoplethysmographic sensor (3), iii. Check whether the specific refill time falls below a specified lower limit, iv. optional output of an alarm if the test shows that the specified lower limit is not reached. System according to Claim 1 , wherein the compression means is a compression bandage, a compression tube or a compression stocking. System according to Claim 1 or 2 wherein the photoplethysmographic sensor (3) comprises a light source for infrared light and a photodetector, wherein the light source is preferably a light-emitting diode and the photodetector is preferably a photodiode. System according to one of the preceding claims, wherein the system comprises a sensor unit (1, 6) with a substrate (2), the photoplethysmographic sensor (3) being arranged on the substrate (2). System according to Claim 4 , the substrate (2) being a printed circuit board, in particular a flexible printed circuit board. System according to Claim 4 or 5 , the sensor unit (1, 6) comprising a data acquisition unit (5), the data acquisition unit (5) being designed to acquire the measured values from the photoplethysmographic sensor (3) and to transmit them to the computer. System according to one of the Claims 4 to 6th , wherein the sensor unit (1, 6) is designed to be adhesive and is provided detached from the compression means, the sensor unit (1, 6) preferably comprising an adhesive backing layer (7). System according to one of the Claims 4 to 6th , wherein the sensor unit (1, 6) is connected to the compression means by the manufacturer. System according to one of the preceding claims, wherein the computer is a mobile device, in particular a smartphone or a tablet. System according to one of the preceding claims, wherein the transmission of the measured values of the photoplethysmographic sensor (3) to the computer takes place wirelessly, the transmission preferably taking place via near-field communication, Bluetooth or a wireless local network. System according to one of the preceding claims, wherein the measurement values from the photoplethysmographic sensor (3) are received immediately after the measurement values have been recorded by the sensor (3). System according to one of the preceding claims, wherein the receiving of the measured values of the photoplethysmographic sensor (3) takes place at the command of a user. System according to any one of the preceding claims, wherein the lower limit is from a range from 10 seconds to 25 seconds, preferably from 15 seconds to 25 seconds, more preferably from 20 seconds to 25 seconds and particularly preferably from 23 seconds to 25 seconds, the lower limit being in particular 25 seconds. System according to one of the preceding claims, wherein in the method for checking the compression therapy it is further checked whether the specific refill time exceeds a predetermined upper limit, an alarm optionally being output if the check shows that the predetermined upper limit is exceeded. System according to Claim 14 , the upper limit being selected from a range from 30 seconds to 180 seconds, preferably from 35 seconds to 90 seconds, more preferably from 40 seconds to 90 seconds and particularly preferably from 45 seconds to 90 seconds, the upper limit being in particular 60 seconds. Computer-implemented method for testing compression therapy, comprising the following steps: i. Generating measured values with a photoplethysmographic sensor (3) during compression therapy in order to check the effectiveness of the compression therapy, ii. Transferring the measured values of the photoplethysmographic sensor (3) during the compression therapy to a computer, iii. Determination of a replenishment time on the basis of the measured values of the photoplethysmographic sensor (3) by the computer, iv. Check by the computer whether the specific replenishment time falls below a specified lower limit, v. optional output of an alarm by the computer if the test shows that the specified lower limit is not reached. Computer program product, comprising instructions which, when the program is executed by a system according to one of the Claims 1 to 15th cause this to follow steps i. to v., steps iii. to v. or at least steps iii. and iv. to Claim 16 to execute. Computer-readable data carrier on which the computer program product is after Claim 17 is stored. Data carrier signal that the computer program product according to Claim 17 transmits.

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